KR20050039025A - Indoor suction structure for window type air-conditioner - Google Patents

Abstract

The present invention relates to an indoor side suction structure of a window type air conditioner, and the present invention is formed by partitioning the outdoor side and the indoor side and the outdoor side to form the outdoor air intake and the air outlet, while the indoor side to the indoor air intake and the air outlet An outdoor heat exchanger formed of a casing to be formed, an outdoor heat exchanger installed on the outdoor side of the casing for heat exchange with outdoor air, and an outdoor fan circulating outdoor air by the outdoor heat exchanger, and an indoor side heat exchanger In a window type air conditioner including an indoor heat exchanger for exchanging indoor air and an indoor heat exchanger including an indoor fan for circulating indoor air with the indoor heat exchanger, the air conditioner is provided between an outlet side of the indoor heat exchanger and an intake side of the indoor fan. Install an indoor orifice that directs indoor air to the indoor fan, By forming the long side to be inclined toward the suction side center of the indoor fan, the resistance of the suction flow path between the indoor heat exchanger and the indoor orifice can be reduced, thereby increasing the air volume by increasing the air intake volume while reducing the flow noise, and indoors. The heat transfer area of the side heat exchanger can be extended to improve air conditioner performance.

Description

Interior suction structure of window type air conditioner {INDOOR SUCTION STRUCTURE FOR WINDOW TYPE AIR-CONDITIONER}

The present invention relates to an indoor side of a window type air conditioner, and more particularly, to an indoor side suction structure of a window type air conditioner formed by inclining the indoor side orifice to widen the suction area to reduce noise and increase the air volume.

In general, an air conditioner (also called an air conditioner) includes a refrigeration cycle device including a compressor, a condenser, a capillary tube, a heat exchanger, and the like. It is a device that keeps the atmosphere of the room comfortable by properly discharging.

Air conditioners can be divided into window type air conditioners and separate type air conditioners according to the installation method. Window-type air conditioners are installed in windows by installing all refrigeration cycle devices in one casing, while separate type air conditioners are divided into indoor units and outdoor units. To install on.

1 is an exploded perspective view showing an example of a conventional window air conditioner, Figure 2 is a cross-sectional view showing a conventional window air conditioner.

As shown in the drawing, a conventional window air conditioner has a casing 10 formed to have a predetermined internal space, an outdoor side heat exchanger 20 installed at one side of the casing 10 to heat-exchange with outdoor air, and a casing ( 10) is installed on the other side in the interior heat exchanger 30 to heat the indoor air.

The casing 10 forms the outdoor air intakes 11 on both sides of the outdoor side, and the outdoor air discharge ports 12 on the front side of the outdoor side.

In addition, the casing 10 forms an indoor air inlet 13 on the front face of the interior side, and an indoor air outlet 14 on the upper half of the front side of the interior, that is, above the indoor air inlet 13. Forming.

The outdoor side heat exchanger 20 is a compressor 21, a condensation heat exchanger 22 that converts the gas refrigerant into a liquid refrigerant while exchanging heat with the outdoor air by connecting the compressor 21 with a refrigerant pipe, and a heat exchanger for condensation. It is composed of an outdoor fan (23) made of an axial fan installed inside the machine (22) to suck the outdoor air and discharge it toward the condensation heat exchanger (22).

The indoor heat exchanger 30 is connected to the heat exchanger 22 for condensation of the outdoor heat exchanger 20 to convert the liquid refrigerant into a low-temperature low-pressure gas refrigerant, and an evaporation heat exchanger 31. The inner fan 32 is formed of a centrifugal fan installed inside the machine 31 to suck air in the room and discharge the air to the evaporation heat exchanger 31.

An indoor orifice 33 for guiding indoor air to the indoor fan 32 is provided between the evaporation heat exchanger 31 and the indoor fan 32, and the indoor fan 32 is disposed above the indoor fan 32. An indoor air guide plate 34 for guiding indoor air passing through the indoor air discharge port 14 is provided.

On the other hand, between the outdoor heat exchanger 20 and the indoor heat exchanger 30 is provided a diaphragm 15 for dividing the inside of the casing 10 into an outdoor side and an indoor side, and the diaphragm 15 is the outdoor fan described above. The fan motor 40 is coupled to the 23 and the indoor fan 32 to transmit rotational force, respectively.

In the drawings, reference numeral 24 denotes an outdoor side shroud and 25 an outdoor side orifice.

The conventional window air conditioner as described above operates as follows.

That is, when power is supplied to the air conditioner, the compressor 21 is driven to circulate the refrigerant, and the fan motor 40 is driven to suck outdoor air and indoor air to the outdoor side and the indoor side, respectively. 22) and heat is exchanged with (31) to discharge.

Looking at this in more detail as follows.

As shown in FIG. 2, the outdoor air is sucked through the outdoor air inlets 11 and 11 provided at both sides of the casing 10 as the axial fan is installed at the outdoor side. With respect to the rear surface, that is to discharge again to the outdoor through the outdoor air discharge port 12 provided forward toward the outdoor. At this time, the outdoor air comes into contact with the heat exchanger 21 for condensation, which is an outdoor heat exchanger, and is discharged as hot air while condensing the refrigerant inside the heat exchanger.

On the other hand, as the centrifugal fan is installed as the indoor fan 32 on the indoor side, the indoor air is sucked through the indoor air suction opening 13 provided in the lower half of the casing 10, and the upper upper half of the casing 10 is provided. It is discharged back to the room through the indoor air discharge port 14 provided perpendicular to the. At this time, the indoor air was in contact with the evaporation heat exchanger 31, which is an indoor heat exchanger, and discharged into the room as cold air while evaporating the refrigerant inside the heat exchanger.

However, in the conventional window type air conditioner as described above, the suction area of the indoor fan 32 is narrower than that of the evaporation heat exchanger 31 as shown in FIG. 3, and the evaporation heat exchanger 31 and the indoor fan ( Although the space t between the two is narrow, the edge of the indoor orifice 33 is formed vertically so that the resistance of the suction flow path to the edge of the evaporating heat exchanger 31 increases, so that the indoor air is mainly a heat exchanger. The heat transfer area of the evaporative heat exchanger 31 is thereby effective only in the range of length L corresponding to the diameter of the suction side of the indoor fan 32 so that the entire evaporative heat exchanger 31 passes through the central portion of the center 31. Of course, the heat transfer performance of the), as well as the air volume decreases while the intake amount of the indoor air decreases, but the flow noise was rather increased.

The present invention has been made in view of the problems of the conventional window type air conditioner, and when the gap between the evaporation heat exchanger and the indoor orifice is narrowly arranged, the heat transfer area of the evaporation heat exchanger can be widened by lowering the suction flow path resistance. In addition, it is an object of the present invention to provide an indoor side suction structure of a window type air conditioner to increase the air volume to improve air conditioner performance and lower the flow noise to increase the reliability of the air conditioner.

In order to achieve the object of the present invention, the casing which is formed by partitioning the outdoor side and the indoor side and the outdoor side to form the outdoor air inlet and the air outlet while the indoor side to form the indoor air inlet and the air outlet, and the casing outdoor The outdoor side heat exchanger which is installed at the side and heat exchanges with the outdoor air and the outdoor heat exchanger which consists of the outdoor fan which circulates the outdoor air by this outdoor side heat exchanger, and the indoor side which is installed at the indoor side of the casing to heat the indoor air In a window type air conditioner comprising a heat exchanger and an indoor heat exchanger including an indoor fan circulating indoor air by the indoor heat exchanger, the indoor air is guided to the indoor fan between an outlet side of the indoor heat exchanger and a suction side of the indoor fan. An indoor orifice is installed, and the edge of the indoor orifice is set to the center of the suction side of the indoor fan. It provides an indoor side suction structure of a window type air conditioner, characterized in that the inclined toward.

Hereinafter, the indoor suction structure of the window type air conditioner according to the present invention will be described in detail based on the embodiment shown in the accompanying drawings.

Figure 4 is an exploded perspective view showing an example of the present invention window air conditioner, Figure 5 is a cross-sectional view showing a window air conditioner of the present invention, Figure 6 is a schematic view showing the indoor side in the window air conditioner of the present invention, Figure 7 is a window air conditioner of the present invention It is a schematic diagram which shows the modification of the interior side.

As shown in the figure, the window-type air conditioner according to the present invention has a predetermined internal space and a casing 110 for forming an indoor air intake 113 on the front vertical surface so as to suck the indoor air from the front, and in the casing 110. It is configured to the outdoor heat exchanger 120 installed on one side to heat exchange with the outdoor air, and the indoor heat exchanger 130 installed on the other side in the casing 110 to heat exchange the indoor air.

The casing 110 forms an outdoor air intake 111 on both sides of the outdoor side perpendicular to the wall of the building, and opens the outdoor air outlet 112 perpendicular to the front side of the outdoor side parallel to the wall of the building. Form.

In addition, the casing 110 forms an indoor air intake port 111 in the lower half of the front side of the interior perpendicular to the wall of the building, and forms an indoor air outlet 112 in the upper half of the front side of the interior.

The outdoor side heat exchanger 120 is installed at one side of the casing to compress the refrigerant into a gas refrigerant of high temperature and high pressure, and is connected to the compressor 121 by a refrigerant pipe to exchange gas refrigerant while exchanging heat with outdoor air. It is composed of a condensation heat exchanger 122 for converting into a liquid refrigerant, and an outdoor fan 123 installed inside the condensation heat exchanger 122 to suck outdoor air and discharge it to the condensation heat exchanger 122.

The heat exchanger 122 for condensation is formed in a substantially rectangular parallelepiped shape so as to accommodate most of the front surface of the outdoor heat exchanger 120 so as to be located between the outdoor air intake 111 and the air outlet 112, and an outdoor fan ( The air 123 sucks air from both sides of the casing 110 to the rear side of the fan 123 through the outdoor air inlets 111 and 111 provided at both sides of the casing 110, and then returns to the rear side of the fan 123. It consists of an axial fan so that it may discharge to the front side of the casing 110 from the outer peripheral side.

The indoor heat exchanger 130 is connected to the heat exchanger 122 for condensation of the outdoor heat exchanger 120 to convert the liquid refrigerant back into a low temperature low pressure gas refrigerant, and an evaporation heat exchanger 131. Installed in the inside of the machine 131 consists of an indoor fan 132 to suck the indoor air and discharge it to the evaporation heat exchanger (131).

The heat exchanger 131 for evaporation is formed in a substantially rectangular parallelepiped shape so as to be positioned between the indoor side air suction port 113 and the air discharge port 114 by accommodating most of the interior front vertical surface of the casing 110, and the indoor fan ( 132 is a circumferential direction toward the indoor air outlet 114 provided on the front inclined surface by sucking the indoor air in the axial direction from the front side through the indoor air inlet 113 provided on the front vertical surface of the casing 110. It consists of a turbo fan which is a kind of centrifugal fan so that it can discharge.

An indoor orifice 133 for guiding indoor air to the suction side of the indoor fan 132 is provided between the evaporation heat exchanger 131 and the indoor fan 132 that is a turbo fan, and above the indoor fan 132. An indoor air guide plate 134 for guiding the indoor air passing through the indoor fan 132 to the indoor air discharge port 114 is installed.

The indoor orifice 133 is formed in a substantially rectangular shape so as to block the indoor heat exchanger 131 and the indoor fan 132, but at the center thereof, the air vent has the same diameter as the suction side of the indoor fan 132. While forming a flow path 133b so as to form a flow path 133b at both edges toward the edge and toward the room fan direction toward the edge, the flow path expansion surface 133b is enlarged so as to form a space 133a. It is desirable to.

Here, the flow path expansion surface 133b is preferably formed to be inclined backward as much as possible in a range that does not overlap with the wing end in consideration of the wing end shape of the indoor fan 132 that is a turbofan.

Meanwhile, a diaphragm 115 is provided between the outdoor heat exchanger 120 and the indoor heat exchanger 110 to divide the inside of the casing 110 into an outdoor side and an indoor side, and the outdoor fan is provided on the diaphragm 115. Both side rotation shafts are respectively coupled to the 123 and the indoor fan 132 to install a fan motor 140 to transmit the rotational force.

In the drawings, reference numeral 124 denotes an outdoor side shroud, and 125 an outdoor side orifice.

The indoor side discharge structure of the window air conditioner of the present invention as described above has the following effects.

That is, when power is supplied to the air conditioner, the compressor 121 is driven to circulate the refrigerant to the condensation heat exchanger 122 and the evaporation heat exchanger 131, and the fan motor 140 is driven together to provide outdoor air and indoors. After each air is sucked into the outdoor and indoor sides of the casing 110, the outdoor air is heat-exchanged with the heat exchanger 122 for condensation, and the indoor air is heat-exchanged with the evaporation heat exchanger 131, respectively. Phase change of the refrigerant) and in the process, the outdoor air is hot air, the indoor air is discharged to the outdoor and indoor air as cold air.

Looking at this in more detail as follows.

As shown in FIG. 5, when the outdoor fan 123 is driven as the axial fan is installed at the outdoor side, the outdoor air is lateral to the outdoor air inlet 111 provided at both sides of the casing 110. At the rear of the outdoor fan 123 is sucked to the rear through the outdoor air discharge port 112 provided forward toward the rear surface, that is to the outside with respect to the interior to the outside again. At this time, the outdoor air contacts the condensation heat exchanger 122, which is an outdoor heat exchanger, absorbs heat from the gas refrigerant of the condensation heat exchanger 122, and turns the gas refrigerant into a high temperature liquid refrigerant and discharges it as hot air. .

On the other hand, by installing a turbo fan which is a centrifugal fan as the indoor fan 132 on the indoor side, the indoor air is sucked from the front through the indoor air intake 113 provided in the lower half of the front side of the casing 110 and then the casing 110. It is discharged back to the room through the indoor air discharge port 114 provided in the front upper half of the). At this time, the indoor air comes into contact with the evaporative heat exchanger 132, which is an indoor side heat exchanger, and releases heat to the liquid refrigerant of the evaporative heat exchanger 132, thereby changing the liquid refrigerant into a gas refrigerant and discharging it into the room. .

Here, as shown in FIG. 6, the indoor air passes through the central portion of the evaporating heat exchanger 131 facing the suction side of the indoor fan 132, is sucked into the indoor fan 132, and at the same time, a flow path of the indoor orifice 133 is provided. The expansion surface 133b also passes near the edge of the evaporating heat exchanger 132 and is sucked into the indoor fan 132. The gap between the evaporation heat exchanger 131 and the indoor orifice 133 is increased toward the edge by the flow path expansion surface 133b of the indoor orifice 133, so that the suction flow path resistance decreases as the suction area becomes wider. Therefore, while the intake of the indoor air increases, the flow noise is reduced.

In addition, as the amount of air intake increases, the air volume of the air conditioner increases to improve performance, and the heat exchange area of the evaporation heat exchanger 131 extends not only to the length L of the center portion, but also to the edge length L1 + L1. The expansion greatly improves the performance of the heat exchanger.

On the other hand, if there is a modification to the indoor side suction structure of the window type air conditioner according to the present invention is as follows.

That is, in the above-described example, the flow path expansion surface 133b is formed to be inclined backward in the indoor fan direction toward the edge of the indoor orifice 133 in the rim direction to actively space the tapered suction end of the indoor fan 132. In this modified example, the flow path expansion surface 233b is formed to incline the center portion of the indoor orifice 233 backward toward the indoor fan 132 to reduce the suction flow path resistance, and at the same time, the heat exchange area for evaporation heat exchange. It extends throughout the longitudinal length L2 of the machine 131. In the figure, 233a is an air vent.

This can be done by placing the indoor fan 132 in its original position and slightly inclining the flow path expansion surface 233b of the indoor orifice 233 or by moving the indoor fan 132 slightly to the rear side, and at the same time the indoor orifice 233. The channel expansion surface 233b may be formed to be inclined at a large angle.

In the former case, the path resistance to indoor air can be slightly reduced while maintaining the length of the indoor / outdoor air conditioner, and the noise, air volume, and heat transfer area can be improved to some extent. By significantly reducing the flow resistance to indoor air, noise, air volume and heat transfer area can be significantly improved.

The indoor suction structure of the window type air conditioner according to the present invention forms an inclined edge of the indoor orifice, thereby reducing the resistance of the suction flow path between the indoor heat exchanger and the indoor orifice, thereby reducing the flow noise and increasing the air intake while increasing the air flow rate. In addition to increasing the heat transfer area of the indoor heat exchanger can be improved air conditioning performance.

1 is an exploded perspective view showing an example of a conventional window type air conditioner,

2 is a cross-sectional view of a conventional window air conditioner,

3 is a schematic view showing the indoor side in a conventional window type air conditioner,

Figure 4 is an exploded perspective view showing an example of the present invention window air conditioner,

Figure 5 is a cross-sectional view showing a window air conditioner of the present invention,

6 is a schematic view showing the indoor side in the present invention window type air conditioner,

Figure 7 is a schematic view showing a modification of the indoor side in the window air conditioner of the present invention.

** Description of the symbols for the main parts of the drawings **

110: casing 111: outdoor air intake

112: outdoor air outlet 113: indoor air intake

114: indoor air outlet 115: diaphragm

120: outdoor side heat exchanger 121: compressor

122: heat exchanger for condensation 123: outdoor fan (axial flow fan)

130: indoor heat exchanger 131: evaporator heat exchanger

132: indoor fan (centrifugal fan) 133,233: indoor orifice

133b, 233b: Euro expansion surface 134: Air guide plate

Claims (4)

It is formed by dividing the outdoor side and the indoor side, and the outdoor side forms the outdoor air inlet and the air outlet, while the indoor side forms the indoor air inlet and the air outlet, and the casing is installed on the outdoor side of the casing to exchange heat with outdoor air. An outdoor side heat exchanger comprising an outdoor side heat exchanger and an outdoor fan circulating outdoor air by the outdoor side heat exchanger, an indoor side heat exchanger installed on the indoor side of the casing to heat the indoor air, and an indoor side heat exchanger In the window type air conditioner including an indoor heat exchanger made of an indoor fan circulating air, An indoor orifice is installed between the outlet side of the indoor heat exchanger and the suction side of the indoor fan to guide the indoor air to the indoor fan, and the edge of the indoor orifice is inclined toward the center of the suction side of the indoor fan. Interior side suction structure of window type air conditioner characterized by the above-mentioned. The method of claim 1, The indoor side orifice is an indoor suction structure of a window type air conditioner, characterized in that the gap is formed to extend from the center of the indoor heat exchanger toward the edge. The method of claim 1, The indoor side orifice is an indoor suction structure of a window type air conditioner, characterized in that the gap is formed so as to extend from the edge of the indoor side heat exchanger toward the center. The method according to claim 2 and 3, The indoor fan is an indoor suction structure of a window type air conditioner, wherein the suction wing is a turbo fan located farther from the center portion of the indoor heat exchanger to the edge.